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Literature DB >> 25320415

Ecobiotechnological Approach for Exploiting the Abilities of Bacillus to Produce Co-polymer of Polyhydroxyalkanoate.

Prasun Kumar¹, Mamtesh Singh², Sanjeet Mehariya², Sanjay K S Patel³, Jung-Kul Lee³, Vipin C Kalia².

Abstract

Ecobiotechnological approach is an attractive and economical strategy to enrich beneficial microbes on waste biomass for production of Polyhydroxyalkanoate (PHA). Here, six strains of Bacillus spp. were used to produce co-polymers of PHA from pea-shells. Of the 57 mixed bacterial cultures (BCs) screened, two of the BCs, designated as 5BC1 and 5BC2, each containing 5 strains could produce PHA co-polymer at the rate of 505-560 mg/l from feed consisting of pea-shell slurry (PSS, 2 % total solids) and 1 % glucose (w/v). Co-polymer production was enhanced from 65-560 mg/l on untreated PSS to 1,610-1,645 mg/l from PSS treated with defined hydrolytic bacteria and 1 % glucose. Supplementation of the PSS hydrolysate with sodium propionate enabled 5BC1 to produce co-polymer P(3HB-co-3HV) with a 3HV content up to 13 % and a concomitant 1.46-fold enhancement in PHA yield. Using the principles of ecobiotechnology, this is the first demonstration of PHA co-polymer production by defined co-cultures of Bacillus from biowaste as feed under non-axenic conditions.

Entities: Chemical

Keywords: Bacillus; Biowaste; Co-polymer; Defined mixed culture; Volatile fatty acid

Year: 2014 PMID： 25320415 PMCID： PMC4188485 DOI： 10.1007/s12088-014-0457-9

Source DB: PubMed Journal: Indian J Microbiol ISSN： 0046-8991 Impact factor: 2.461

29 in total

1. Polyhydroxyalkanoate (PHA) production by a mixed microbial culture using sugar molasses: effect of the influent substrate concentration on culture selection.

Authors: M G E Albuquerque; C A V Torres; M A M Reis
Journal: Water Res Date: 2010-03-31 Impact factor: 11.236

2. Effect of substrate load and nutrients concentration on the polyhydroxyalkanoates (PHA) production using mixed consortia through wastewater treatment.

Authors: M Venkateswar Reddy; S Venkata Mohan
Journal: Bioresour Technol Date: 2012-03-03 Impact factor: 9.642

3. Polyhydroxybutyrate production from lactate using a mixed microbial culture.

Authors: Yang Jiang; Leonie Marang; Robbert Kleerebezem; Gerard Muyzer; Mark C M van Loosdrecht
Journal: Biotechnol Bioeng Date: 2011-05-31 Impact factor: 4.530

4. Rapid quantification of intracellular PHA using infrared spectroscopy: an application in mixed cultures.

Authors: Mónica V Arcos-Hernandez; Nicholas Gurieff; Steven Pratt; Per Magnusson; Alan Werker; Alejandro Vargas; Paul Lant
Journal: J Biotechnol Date: 2010-09-17 Impact factor: 3.307

5. Mixed-culture polyhydroxyalkanoate production from olive oil mill pomace.

Authors: James L Waller; Peter G Green; Frank J Loge
Journal: Bioresour Technol Date: 2012-06-16 Impact factor: 9.642

6. Production of Polyhydroxyalkanoate Co-polymer by Bacillus thuringiensis.

Authors: Mamtesh Singh; Prasun Kumar; Sanjay K S Patel; Vipin C Kalia
Journal: Indian J Microbiol Date: 2012-08-03 Impact factor: 2.461

7. Potential of Bacillus sp. to produce polyhydroxybutyrate from biowaste.

Authors: T Kumar; M Singh; H J Purohit; V C Kalia
Journal: J Appl Microbiol Date: 2009-02-16 Impact factor: 3.772

8. Hydrogen and polyhydroxybutyrate producing abilities of microbes from diverse habitats by dark fermentative process.

Authors: Shalini Porwal; Tarika Kumar; Sadhana Lal; Asha Rani; Sushil Kumar; Simrita Cheema; Hemant J Purohit; Rakesh Sharma; Sanjay Kumar Singh Patel; Vipin Chandra Kalia
Journal: Bioresour Technol Date: 2007-12-20 Impact factor: 9.642

9. Enrichment of a mixed bacterial culture with a high polyhydroxyalkanoate storage capacity.

Authors: Katja Johnson; Yang Jiang; Robbert Kleerebezem; Gerard Muyzer; Mark C M van Loosdrecht
Journal: Biomacromolecules Date: 2009-04-13 Impact factor: 6.988

10. Bacillus subtilis as potential producer for polyhydroxyalkanoates.

Authors: Mamtesh Singh; Sanjay Ks Patel; Vipin C Kalia
Journal: Microb Cell Fact Date: 2009-07-20 Impact factor: 5.328

20 in total

Review 1. Microbial Cometabolism and Polyhydroxyalkanoate Co-polymers.

Authors: Subhasree Ray; Vipin Chandra Kalia
Journal: Indian J Microbiol Date: 2016-09-28 Impact factor: 2.461

2. Dark-Fermentative Biological Hydrogen Production from Mixed Biowastes Using Defined Mixed Cultures.

Authors: Sanjay K S Patel; Jung-Kul Lee; Vipin C Kalia
Journal: Indian J Microbiol Date: 2017-03-09 Impact factor: 2.461

3. Effect of glucose and olive oil as potential carbon sources on production of PHAs copolymer and tercopolymer by Bacillus cereus FA11.

Authors: Farha Masood; Maria Abdul-Salam; Tariq Yasin; Abdul Hameed
Journal: 3 Biotech Date: 2017-05-13 Impact factor: 2.406

Ecobiotechnological Approach for Exploiting the Abilities of Bacillus to Produce Co-polymer of Polyhydroxyalkanoate.

1. Polyhydroxyalkanoate (PHA) production by a mixed microbial culture using sugar molasses: effect of the influent substrate concentration on culture selection.

2. Effect of substrate load and nutrients concentration on the polyhydroxyalkanoates (PHA) production using mixed consortia through wastewater treatment.

3. Polyhydroxybutyrate production from lactate using a mixed microbial culture.

4. Rapid quantification of intracellular PHA using infrared spectroscopy: an application in mixed cultures.

5. Mixed-culture polyhydroxyalkanoate production from olive oil mill pomace.

6. Production of Polyhydroxyalkanoate Co-polymer by Bacillus thuringiensis.

7. Potential of Bacillus sp. to produce polyhydroxybutyrate from biowaste.

8. Hydrogen and polyhydroxybutyrate producing abilities of microbes from diverse habitats by dark fermentative process.

9. Enrichment of a mixed bacterial culture with a high polyhydroxyalkanoate storage capacity.

10. Bacillus subtilis as potential producer for polyhydroxyalkanoates.

Review 1. Microbial Cometabolism and Polyhydroxyalkanoate Co-polymers.

2. Dark-Fermentative Biological Hydrogen Production from Mixed Biowastes Using Defined Mixed Cultures.

3. Effect of glucose and olive oil as potential carbon sources on production of PHAs copolymer and tercopolymer by Bacillus cereus FA11.

4. Integrative Approach for Producing Hydrogen and Polyhydroxyalkanoate from Mixed Wastes of Biological Origin.

Review 5. Biomedical Applications of Polyhydroxyalkanoates.

6. Co-utilization of Crude Glycerol and Biowastes for Producing Polyhydroxyalkanoates.

Review 7. Aligning Microbial Biodiversity for Valorization of Biowastes: Conception to Perception.

Review 8. Mapping Microbial Capacities for Bioremediation: Genes to Genomics.

Review 9. Biorefinery for Glycerol Rich Biodiesel Industry Waste.

10. Ecobiotechnological strategy to enhance efficiency of bioconversion of wastes into hydrogen and methane.